Silicon Laboratories Si5365-EVB User manual

Brand: Silicon Laboratories

Model: Si5365-EVB

Type: User manual

This manual is also suitable for

Si5365/66-EVB

Si5367/68-EVB

Si5369-EVB

Si5365/66/67/68/69 E

VALUATION BOARD USER’S GUIDE

1. Introduction

The Si5365/66-EVB,Si5367/68-EVB, and Si5369-EVB provide platforms for evaluating Silicon Laboratories'

Si5365/Si5366, Si5367/Si5368, and Si5369 Any-Frequency Precision Clocks. The Si5365 and Si5366 are

controlled directly using configuration pins on the devices, while the Si5367, Si5368, and Si5369 are controlled by

a microprocessor or MCU (microcontroller unit) via an I

C or SPI interface. The Si5365 and Si5367 are low jitter

clock multipliers with a loop bandwidth ranging from 30 kHz to 1.3 MHz. The Si5366 and Si5368 are jitter-

attenuating clock multipliers, with a loop bandwidth ranging from 60 Hz to 8.4 kHz. The Si5369 is similar to the

Si5368, with a much lower loop BW of from 4 to 525 Hz. The Si5366 device can optionally be configured to operate

as a Si5365, so a single evaluation board is available to evaluate both devices. Likewise, the Si5368 can be

configured to operate as a Si5367, so the two devices share a single evaluation board.

The Si5365/66/67/68/69 Any-Frequency Precision Clocks are based on Silicon Laboratories' 3rd-generation

DSPLL

technology, which provides any-frequency synthesis in a highly integrated PLL solution that eliminates the

need for external VCXO and loop filter components. The devices have excellent phase noise and jitter

performance. The Si5366, Si5368, and Si5369 jitter attenuating clock multipliers support jitter generation of 0.3 ps

RMS (typ) across the 12 kHz–20 MHz and 50 kHz–80 MHz jitter filter bandwidths. The Si5365 and SI5367 support

jitter generation of 0.6 ps RMS (typ) across the 12 kHz–20 MHz and 50 kHz–80 MHz jitter filter bandwidths. For all

devices, the DSPLL loop bandwidth is digitally programmable, providing jitter performance optimization at the

application level. These devices are ideal for providing clock multiplication/clock division, jitter attenuation, and

clock distribution in mid-range and high performance timing applications.

Figure 1. Si536x TQFP EVB

Top

Bottom

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

2 Rev. 0.6

2. Applications

The Si536x Any-Frequency Precision Clocks have a comprehensive feature set, including any-frequency

synthesis, multiple clock inputs, multiple clock outputs, alarm and status outputs, hitless switching between input

clocks, programmable output clock signal format (LVPECL, LVDS, CML, CMOS), output phase adjustment

between output clocks, and output phase adjustment between all output clocks and the selected reference input

clock (phase increment/decrement). For more details, consult the Silicon Laboratories timing products website at

www.silabs.com/timing.

Both evaluation boards (EVBs) have a Silicon Laboratories MCU (C8051F340) that supports USB communications

with a PC host. For the pin controlled parts (Si5365 and Si5366), the pin settings of the devices are determined by

the MCU and the PC resident software that is provided with the EVB. For the MCU controlled parts (Si5367,

Si5368, and Si5369), the devices are controlled and monitored through the serial port (either SPI or I

C). A CPLD

sits between the MCU and the Precision Clock device that performs voltage level translation and stores the pin

configuration data for the pin controlled devices. Jumper plugs are provided so that the user can bypass the MCU/

CPLD to manually control the pin controlled devices. Ribbon headers and SMA connectors are included so that

external clock in, clock out and status pins can be easily accessed by the user. For the MCU controlled devices

(Si5367, Si5368, and Si5369)), the user also has the option of bypassing the MCU and controlling the parts from an

external serial device. On-board termination is included so that the user can evaluate either single-ended or

differential as well as ac or dc coupled clock inputs and outputs. A separate DUT (device under test) power supply

connector is included so that the Precision Clocks can be run at either 1.8, 2.5, or 3.3 V, while the USB MCU

remains at 3.3 V. LEDs are provided for convenient monitoring of key status signals.

For more detailed information about these devices, refer to the Any-Frequency Precision Clock Family Reference

Manual.

Table 1. Features by Part Number

Device PN

# Clock Inputs

# Clock Outputs

Control

Input Freq

(MHz)

Output Freq

(MHz)

Jitter Generation

(12 kHz–20 MHz)

Prog. Loop BW

Clock Mult.

Hitless Switching

Alarms

Package

Precision Clock Multipliers

Si5365 4 5 Pin 15 to

707

19 to

1050

0.6 ps

rms typ

30 kHz–1.3 MHz Y N LOS, FOS 14 x 14

100-TQFP

Si5367 4 5 I

C or

SPI

10 to

710

10 to

1400

0.6 ps

rms typ

30 kHz–1.3 MHz Y N LOS, FOS 14 x 14

100-TQFP

Any-Frequency Precision Clock Multipliers with Jitter Attenuation

Si5366 4 5 Pin .008 to

707

.008 to

1050

0.3 ps

rms typ

60 Hz–8.4 kHz Y Y LOL, LOS,

FOS

14 x 14

100-TQFP

Si5368 4 5 I

C or

SPI

.002 to

710

.002 to

1400

0.3 ps

rms typ

60 Hz–8.4 kHz Y Y LOL, LOS,

FOS

14 x 14

100-TQFP

Si5369 4 5 I

C or

SPI

.002 to

710

.002 to

1400

0.3 ps

rms typ

4 Hz–525 Hz Y Y LOL, LOS,

FOS

14 x 14

100-TQFP

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

Rev. 0.6 3

3. Features

The Si5365/66-EVB, Si5367/68-EVB, and Si5369-EVBs each include the following:

 CD with documentation and EVB software including the DSPLLsim configuration software utility

 USB cable

 EVB circuit board including a Si5366 (Si5365/66-EVB), a Si5368 (Si5367/68-EVB), or a Si5369 (Si5369-EVB)

 User's Guide (this document)

4. Si5365/66-EVB, Si5367/68-EVB, and Si5369-EVB Quick Start

1. Install the Precision Clock EVB Driver. (This must be installed before the EVB is connected to the PC via the

USB cable.) For details, see Section "7.EVB Software Installation" on page 12.

2. Install the Precision Clock EVB Software. (Assumes that Microsoft .NET Framework 3.1 is already installed.)

3. Connect the two power supplies to the EVB. One is 3.3 V and the other is either 1.8, 2.5, or 3.3 V. The DUT is

4. Turn on the power supplies.

5. Connect a USB cable from the EVB to the PC where the software was installed.

6. Install USB driver.

7. Launch software by clicking on Start

ProgramsSilicon LaboratoriesPrecision Clock EVB Software

and selecting one of the programs.

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

4 Rev. 0.6

5. Functional Description

The Si5365/66-EVB, Si5367/68-EVB, Si5369-EVB, and DSPLLsim software allow for a complete and simple

evaluation of the functions, features, and performance of the Si536x Any-Frequency Precision Clocks.

5.1. Narrowband versus Wideband Operation

This document describes three evaluation boards: one for the Si5365 and Si5366, another for the Si5367 and

Si5368, and a third for the Si5369. The first evaluation board is for pin controlled clock parts, the second is for clock

parts that are to be controlled by an MCU over a serial port, and the third is for a very low loop bandwidth device

that is also controlled by an MCU. Two of the boards supports two parts: one that is wideband (the Si5365 and the

Si5367) and the one that is narrowband (the Si5366 and the Si5368). The third board only supports the low loop

bandwidth narrowband Si5369. The narrowband parts other than the Si5369 are both capable of operating in the

wideband mode, so evaluation of the wideband parts can be done by using a narrowband part in wideband mode.

As such, these evaluation boards are only populated with narrowband parts.

To evaluate Si5365 device operation using the Si5365/66-EVB, the RATE[1:0] pins must be set to HH using the

jumper provided. To evaluate Si5367 device operation using the Si5367/68-EVB, the Precision Clock EVB

Software should be configured for wideband mode. For details, see the Precision Clock EVB Software

documentation that can be found on the enclosed distribution CD.

5.2. Block Diagram

Figure 2 is a block diagram of the evaluation board. The MCU communicates to the host PC over a USB

connection. The MCU controls and monitors the Si536x through the CPLD. The CPLD, among other tasks,

translates the signals at the MCU voltage level of 3.3 V to the Si536x's voltage level, which is nominally 3.3, 2.5, or

1.8 V. The user has access to all of the Si536x's pins using the various jumper settings as well as through the host

PC via the MCU and CPLD.

Figure 2. Si536x TQFP Block Diagram

USB

MCU

SPI bus

CPLD

+3.3 V

DUT PWR

+1.8 V

Vreg

Reset

switch

LEDs

SPI bus

1.8 to 3.3 V

reg addr

Si536x

Output

SMAs

Input

SMAs

Ext RefClk

Jumper

Headers

Terminate

status signals

SPI, I

C signals

Control signals

CKOUT1

CKOUT2

CKOUT3

CKOUT4

FSOUT

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

Rev. 0.6 5

5.3. Si536x Input and Output Clocks

The Si536x has four differential inputs that are ac terminated to 50  and then ac coupled to the part. Single ended

operation can be implemented by simply not connecting to one of the two of the differential pairs. When operating

with clock inputs of 1 MHz or less in frequency, the appropriate dc blocking capacitors (C58, C61, C47, C50, C53,

C55, C42 and C45) located on the bottom of the board should be replaced with zero ohm resistors. The reason for

this is that the capacitive reactance of the ac coupling capacitors becomes significant at low frequencies. It is also

important that the CKIN signal meet the minumum rise time of 11 ns (CKNtrf) even though the input frequency is

low.

The four clock outputs are all differential, ac coupled and configured for driving 50  transmission lines. When

using single ended outputs, it is important that the unused half of the output be terminated. Given that the

Frame Sync signal can have a duty cycle that is far from 50%, the Frame Sync outputs are dc coupled. If the

Frame Sync or other clock ouputs signals are configured for CMOS, then the two outputs are not complements of

one another and should be wired in parallel so that the output drive current is doubled. To evaluate CMOS level

Frame Sync outputs, a 0  resistor should be installed at R19. Note that for the MCU controlled parts that support

Frame Sync mode (Si5367 and Si5368), the Frame Sync output signal format can be configured independently of

the other four outputs.

Two jumpers are provided to assist in monitoring the Si536x power. When R36 is removed, J25 can be used to

measure the device current. J18 can be used at any time to monitor the supply voltage at the device.

The Si5366, Si5368, and Si5369 require that an external reference clock be provided to enable the devices to

operate as narrowband jitter attenuators with loop bandwidths as low as 60 Hz (as low as 4 Hz for the Si5369). The

external reference clock can be either a crystal, a stand-alone oscillator or some other clock source. The range of

acceptable reference frequencies is described in the Any-Frequency Precision Clocks Family Reference Manual

(Si53xx-RM). The EVB's are shipped with a 3rd overtone 114.285 MHz crystal that is used in the majority of

applications. J1 and J2 are used when the Si536x is to be configured in narrowband mode with an external

reference oscillator (i.e., without using the 114.285 MHz crystal).

The RATE pins should also be configured for the desired mode, either through DSPLLsim or using the jumper

plugs at J17 (see Table 7 on page 11).

Table 2 shows how the various components should be configured for the three modes of operation:

For a differential external reference, connect the balanced input signals to J1 and J2. For single-ended operation,

connect the input signal to J1 and disconnect J2.

R51 is provided so that a different termination scheme can be used. If R51 is populated, then remove R52 and R24.

Table 2. Reference Input Mode

Mode

Xtal

38.88 MHz Ext

Ref

Wideband

Input 1 NC

J1 NC

Input 2 NC J2 NC

C39 NOPOP

install install

C22 NOPOP install NOPOP

R50 NOPOP NOPOP install

R28 install NOPOP NOPOP

RATE0 M—H

RATE1 M—H

Notes:

1. Xtal is 114.285 MHz 3rd overtone.

2. For external reference frequencies and RATE pin settings, see the

Any-Frequency Precision Clock Family Reference Manual.

3. NC—no connect.

4. NOPOP—do not install this component.

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

6 Rev. 0.6

5.4. CPLD

This CPLD is required for the MCU to control an Si536x operating at either 1.8, 2.5, or 3.3 V. The CPLD provides

two main functions: it translates the voltage level from 3.3 V (the MCU voltage) to the Si536x voltage (either 1.8,

2.5, or 3.3 V). The MCU communicates to the CPLD with the SPI signals SS_CPLD_B (slave select), MISO

(master in, slave out), MOSI (master out, slave in) and SCLK. The MCU can talk to CPLD-resident registers that

are connected to pins that control the Si536x's pins, mainly for pin control mode. When the MCU wishes to access

a Si536x register, the SPI signals are passed through the CPLD, while being level translated, to the Si536x. The

CPLD is an EE device that is retains its code that is loaded through the JTAG port (J32). The core of the CPLD

runs at 1.8 V, which is provided by voltage regulator U4. The CPLD also logically connects many of the LEDs to the

appropriate Si536x pins.

Figure 3. SPI Mode Serial Data Flow

5.5. MCU

The MCU communicates with the PC over USB so that PC resident software can be used to control and monitor

the Si536x. The USB connector is J6 and the debug port, by which the MCU is flashed, is J31. The reset switch,

SW1, resets the MCU, but not the CPLD. The MCU is a self-contained USB master and runs all of the code

required to control and monitor the Si536x, both in the MCU mode and in the pin-controlled modes.

U3 contains a unique serial number for each board and U5 is an EEPROM that is used to store configuration

information for the board. The board powers up in free run mode with a configuration that is outlined in "Appendix—

Powerup and Factory Default Settings" on page 25. For the pin controlled parts (Si5365/66-EVB), the contents of

U5 configure the board on power up so that jumper plugs may be used. If DSPLLsim is subsequently run, the

jumper plugs should be removed before DSPLLsim downloads the configuration to the EVB so that the jumpers do

not conflict with the CPLD outputs. For microprocessor parts, U5 configures the EVB for a specific frequency plan

as described in "Appendix—Powerup and Factory Default Settings" on page 25.

The Evaluation board has a serial port connector (J22) that supports the following:

 Control by the MCU/CPLD of an Any-Frequency part on an external target board.

 Control of the Any-Frequency part that is on the Evaluation board through an external SPI or I

C port.

For details, see J22 (Table 6).

Though they are not needed on this Evaluation Board because the CPLD has low output leakage current, some

applications will require the use of external pullup and pulldown resistors when three level pins are being driven by

external logic drivers. This is particularly true for the pin-controlled parts: the Si5365 and Si5367. Consult the

Si53xx-RM Any-Frequency Precision Clock Family Reference Manual for details.

LVPECL outputs will not function at 1.8 V. If the Si536x part is to be operated at 1.8 V, the output format

needs to be changed by altering either the SFOUT pins (Si5365/66) or the SFOUT register bits (Si5367/68/

69).

MCU CPLD Si5367, Si5368

SS_CPLD_B

SCLK

MOSI

MISO

SS_B

SCLK

SDI

SDO

DUT_PWR

+3.3 V

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

Rev. 0.6 7

5.6. Power and 2L Signals

This evaluation board requires two power inputs +3.3 V for the MCU and either 1.8, 2.5, or 3.3 V for the Any-

Frequency Precision Clock part. The power connector is J40. The grounds for the two supplies are tied together on

the EVB. There are sixteen LEDs, as described in Table 3. J14 is a three by 10 pin male header by which the user

can manually set the values of the two-level inputs using jumper plugs connected to either ground (silkscreen

labeled L) or the power supply (labeled H). J8 is a twenty pin ribbon header that brings out all of the status outputs

from the Si536x. Note that some pins are shared and serve as both inputs and outputs, depending on how the

device is configured. For users that wish to remotely access the input and output pins settings with external

hardware, J14 and J8 can be connected to ribbon cables.

5.7. 3L Pins

The three-level inputs can all be manually configured by installing jumper plugs at J17, either H or L. The M level is

achieved by not installing a jumper plug at a given location. J17 can also be used as a connection to an external

circuit that controls these pins. J22 is a ten pin ribbon header that is provided so that an external processor can

control the Si536x over either the SPI or I

C bus.

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

8 Rev. 0.6

6. Connectors and LEDs

6.1. LEDs

There are sixteen LEDs on the board which provide a quick and convenient means of determining board status.

Table 3. LED Status and Description

LED Color Label LED Color Label

D1 green 3.3 V D2 red LOL

D3 green DUT_PWR D4 red C1B

D5 red ALRMOUT D6 red C2B

D7 yellow CPLD_2 D8 red C3B

D9 yellow CPLD_1 D10 green C1A

D11 red MCU_3 D12 green C2A

D13 red MCU_2 D14 green C3A

D15 red MCU_1 D16 green C4A

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

Rev. 0.6 9

6.2. User Jumpers and Headers.

Use Figure 4 to locate the jumpers described in Tables 4, 5, 6, and 7:

Figure 4. Connectors, Jumper Header Locations

J25 assists in measuring the Any-Frequency Precision Clock current draw. If J25 is to be used, R36 should be

removed.

R24, R28, C22 on top;

R50, R51, R52, C39 on bot

J18

Ext Ref, J1, J2

J17

J14

J22

J25, R36

C22

R24, R28, C22 on top;

R50, R51, R52, C39 on bot

J18

Ext Ref, J1, J2

J17

J14

J22

J25, R36

C22

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

10 Rev. 0.6

J14 is a three-pin by ten header that is used to establish input levels for the pin controlled two-level inputs using

jumper plugs. It also provides a means of externally driving the two-level input signals:

J8 is a 20 pin ribbon header that provides an external path to monitor the status pins.

J22 is a 10 pin ribbon header that provides an external path to serially communicate with the Any-Frequency

Precision Clock.

To control the Any-Frequency part that is on the Evaluation Board from an external serial port, open the Register

Programmer, connect to the Evaluation Board, go to Options in the top toolbar and select "Switch To External

Control Mode".

To control an Any-Frequency part that is on an external target board from the Evaluation Board using its serial port,

tie pin 9 of J22 low so that the on-board Any-Frequency part is constantly being held in reset. This will force it to

disable its SDA_SDO output buffer.

Table 4. Two-Level Input Jumper Header, J14

J36 Pin Comment

J14.1B CS0_C3A CS0

J14.2B CS1_C4A CS1

J14.3B INC

J14.4B DEC

J14.5B — not used

J14.6B — not used

J14.7B DSBL34

J14.8B FS_ALIGN

J14.9B FS_SW

J14.10B CK_CONF

Table 5. External Status Connector, J8

J37 Pin Comment

J8.1 LOL

J8.3 C1B

J8.5 C2B

J8.7 C3B

J8.9 C1A

J8.11 C2A

J8.13 CS0_C3A C3A

J8.15 CS1_C4A C4A

J8.17 INT_ALRM

J8.19 DUT_PWR

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

Rev. 0.6 11

J17 is a three-pin by twenty header that is used to establish input levels for the pin controlled three-level inputs

using jumper plugs. It also provides a means of externally driving the three-level input signals.

J18 is used to monitor the Any-Frequency Precision Clock voltage.

J1 and J2 are edge mount SMA connectors that are used, if so configured, to supply an external single-ended or

differential reference oscillator.

Table 6. External Serial Port Connector, J22

J38 Pin Comment

J22.1 SDA_SDO

J22.3 SCL_SCLK

J22.5 SDI

J22.7 A2_SS

J22.9 DUT_RST_B reset

Table 7. Three-Level Input Jumper Headers, J17

J39 Pin Comment

J17.1B CMODE

J17.2B AUTOSEL

J17.3B A0_FRQSEL0

J17.4B A1_FRQSEL1

J17.5B A2_SS_FRQSEL2

J17.6B SDI_FRQSEL3

J17.7B SCL_SCLK_BWSEL0

J17.8B SDA_SDO_BWSEL1

J17.9B FRQTBL

J17.10B DBL2_BY

J17.11B BDBL_FS

J17.12B DIV34_0

J17.13B DIV34_1

J17.14B SFOUT0

J17.15B SFOUT1

J17.16B RATE0

J17.17B RATE1

J17.18B FOS_CTL

J17.19B — not used

J17.20B — not used

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

12 Rev. 0.6

7. EVB Software Installation

The release notes and the procedure for installing the EVB software can be found on the release CD included with

the EVB. These items can also be downloaded from the Silabs web site: www.silabs.com/timing. Follow the links

for 1-PLL Jitter attenuators, and look under the Tools tab.

7.1. Precision Clock EVB Software Description

There are several programs to control the Precision Clock device. Each provides a different kind of access to the

device. Refer to the online help in each program by clicking Help

Help in the menu for more information on how

to use the software. Note: Some of the Precision Clock devices do not have a register map, so some programs

may not be applicable to them.

Table 8. User Applications

Program Description

The Register Viewer displays the current register map data in a table format sorted by reg-

ister address to provide an overview of the device’s state. This program can save and print

the register map.

The Register Programmer provides low-level register control of the device. Single and

batch operations are provided to read from and write to the device. Register map files can

be saved and opened in the batch mode.

Setting Utility

This application allows for quick access to each control on the Precision Clock device

(either pin- or register-based). It can save and open text files as well.

DSPLLsim

The DSPLLsim provides high-level control of the Precision Clock device. It has the fre-

quency planning wizard as well as control of the pins and registers in a organized, intuitive

manner.

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

Rev. 0.6 13

8. Schematics

Figure 5. Si536x

DUT_PWR

RATE0

RATE1

DSBL34

INT_ALRM

CS0_C3A

CS1_C4A

C1A

C2A

C3B

C1B

C2B

SFOUT1

DBL_FS

SFOUT0

LOL

AUTOSEL

A0_FRQSEL0

SDA_SDO_BWSEL1

A2_SS_FRQSEL2

A1_FRQSEL1

SDI_FRQSEL3

FRQTBL

CK_CONF

CMODE

INC

FOS_CTL

DEC

DIV34_0

DIV34_1

DBL2_BY

SCL_SCLK_BWSEL0

FS_SW

FS_ALIGN

DUT_RST_B

ExtRefIn+

CKIN1+

CKIN1-

CKIN2+

CKIN2-

CKIN3+

CKIN3-

CKIN4-

CKIN4+

CKOUT1+

CKOUT1-

CKOUT2+

CKOUT2-

CKOUT3+

CKOUT3-

CKOUT4-

CKOUT4+

FS_OUT+

FS_OUT-

for CMOS

output

to measure

DUT current

Locate

to U1

See note 1

ExtRefIn-

to power

plane

C53100N C53100N

J37

SMA_EDGE

J37

SMA_EDGE

C58100N C58100N

C22

10NF

NOPOP

C22

10NF

NOPOP

C44

100N

C44

100N

R30

0 ohm

NOPOP

R30

0 ohm

NOPOP

C32

100N

C32

100N

C59

10NF

C59

10NF

C55100N C55100N

J39

SMA_EDGE

J39

SMA_EDGE

R500 ohm

NOPOP

R500 ohm

NOPOP

C39

10NF

NOPOP

C39

10NF

NOPOP

C46

10NF

C46

10NF

R54

49.9

R54

49.9

C28

100N

C28

100N

R280 ohm R280 ohm

J30

SMA_EDGE

J30

SMA_EDGE

C48

10NF

C48

10NF

J10

SMA_EDGE

J10

SMA_EDGE

C25

100N

C25

100N

J35

SMA_EDGE

J35

SMA_EDGE

J18J18

R5349.9 R5349.9

C17

100N

C17

100N

R61

49.9

R61

49.9

C54

10NF

C54

10NF

1 3

2 4

GND

114.285 MHz

GND

114.285 MHz

C42100N C42100N

R2449.9 R2449.9

R31

0 ohm

R31

0 ohm

C52

1UF

C52

1UF

R57

49.9

R57

49.9

R56 49.9R56 49.9

SMA_EDGE

C29

100N

C29

100N

J23

SMA_EDGE

J23

SMA_EDGE

J15

SMA_EDGE

J15

SMA_EDGE

C56

10NF

C56

10NF

C26

100N

C26

100N

C62

10NF

C62

10NF

C24

10NF

C24

10NF

C19

100N

C19

100N

SMA_EDGE

C47100N C47100N

R59

49.9

R59

49.9

R29

0 ohm

R29

0 ohm

C33

100N

C33

100N

C61100N C61100N

C57

100N

C57

100N

C51

10NF

C51

10NF

C43 10NFC43 10NF

J38

SMA_EDGE

J38

SMA_EDGE

J33

SMA_EDGE

J33

SMA_EDGE

J25

NOPOP

J25

NOPOP

R36

0 ohm

R36

0 ohm

J41

SMA_EDGE

J41

SMA_EDGE

J21

SMA_EDGE

J21

SMA_EDGE

1 2

Ferrite

C60

100N

C60

100N

C40

100N

C40

100N

R5249.9 R5249.9

J36

SMA_EDGE

J36

SMA_EDGE

100N

R60

49.9

R60

49.9

100N

J13

SMA_EDGE

J13

SMA_EDGE

C41

10NF

C41

10NF

R55

49.9

R55

49.9

Vdd1

Vdd2

Vdd3

Vdd4

Vdd5

Vdd6

Vdd7

Vdd9

Vdd8

Vdd10

Vdd11

Vdd12

Vdd13

Vdd14

Vdd15

Vdd16

Vdd17

100

Gnd1

Gnd2

Gnd3

Gnd4

Gnd5

Gnd6

Gnd7

Gnd8

Gnd9

Gnd10

Gnd11

Gnd12

Gnd13

Gnd14

Gnd15

Gnd16

Gnd_Slug

101

NC1

NC2

NC3

NC4

NC5

NC6

NC7

NC8

NC9

NC10

NC11

CKIN1+

CKIN1-

CKIN2+

CKIN2-

CKIN3+

CKIN3-

CKIN4+

CKIN4-

CKOUT1+

CKOUT1-

CKOUT2+

CKOUT2-

CKOUT3+

CKOUT3-

CKOUT4+

CKOUT4-

FS_OUT+

FS_OUT-

SFOUT0

SFOUT1

LOL

C1B

C2B

C3B

ALRMOUT

RSTB

RATE0

RATE1

INC

DEC

FRQSEL3_SDI

FRQSEL2_A2_SS

FRQSEL1_A1

FRQSEL0_A0

AUTOSEL

CS0_C3A

DIV34_0

DIV34_1

CS1_C4A

SCL_SCLK_BWSWL0

SDA_SDO_BWSEL1

DSBL34

DBL2_BY

FS_SW

FS_ALIGN

DBL_FS

CK_CONF

CMODE

FOS_CTL

NC13

NC12

FRQTBL

C1A

C2A

Si536x

SMA_EDGE

J28

SMA_EDGE

J28

SMA_EDGE

C27

100N

C27

100N

C45100N C45100N

C49

100N

C49

100N

R51100

NOPOP

R51100

NOPOP

J29

SMA_EDGE

J29

SMA_EDGE

C50100N C50100N

Notes:

1. Change for Si5365, Si5367, and External Reference.

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

14 Rev. 0.6

TMS

TDO

TCK

VCCAUX

TDI

V1P8

V3P3

DUT_PWR V3P3

REG_ADR0

REG_ADR1

REG_ADR2

REG_ADR3

SS_CPLD_B

MOSI

SCLK

MISO

CPLD_IRQ

REG_ADR4

CPLD_LED2

CPLD_LED1

CPLD_LED0

MCU_SPARE1

CPLD_RST_B

CPLD_LED3

CPLD_LED4

CPLD_LED5

CPLD_LED6

CPLD_LED7

CPLD_LED8

CPLD_LED9

MCU_SPARE2

LOL

A0_FRQSEL0

A1_FRQSEL1

A2_SS_FRQSEL2

SDI_FRQSEL3

SCL_SCLK_BWSEL0

SDA_SDO_BWSEL1

DUT_RST_B

CMODE

INT_ALRM

RATE0

RATE1

CK_CONF

FOS_CTL

DBL2_BY

DSBL34

AUTOSEL

FRQTBL

SFOUT0

SFOUT1

C1A

C2A

CS0_C3A

CS1_C4A

DIV34_0

DIV34_1

FS_ALIGN

FS_SW

DBL_FS

INC

DEC

C1B

C2B

C3B

CPLD_LED10

CPLD_SPARE4

CPLD_SPARE5

CPLD_SPARE6

CPLD_SPARE7

CPLD_SPARE8

CPLD_SPARE9

CPLD_SPARE10

CPLD_SPARE11

CPLD_SPARE12

CPLD_SPARE13

CPLD_SPARE14

CPLD_SPARE1

CPLD_SPARE2

CPLD_SPARE15

CPLD_SPARE16

DUT_PWR +3.3V

JTAG

connector

1.8V

1UF

FN5_M4_GCK1

FN5_M6_GCK0

FN6_M2_CDRST

FN6_M4_GCK2

FN6_M12_DGE

FN6_M14

FN6_M16

FN7_M5

FN7_M6

FN7_M11

FN7_M12

FN7_M13

FN7_M14

FN8_M6

FN8_M11

FN8_M12

FN8_M13

FN8_M14

FN8_M15

FN13_M2

FN13_M4

FN13_M6

FN13_M13

FN14_M1

FN14_M3

FN14_M5

FN14_M14

FN14_M15

FN15_M11

FN15_M12

FN15_M13

FN15_M14

FN15_M15

FN15_M16

FN16_M5

FN16_M6

FN16_M11

FN16_M12

FN16_M13

FN1_M3_GSR

FN1_M6

FN1_M12

FN1_M13

FN1_M14

FN2_M1_GTS2

FN2_M3_GTS3

FN2_M5_GTS0

FN2_M12_GTS1

FN2_M14

FN2_M15

FN3_M5

FN3_M12

FN3_M14

FN3_M16

FN4_M1

FN4_M2

FN4_M3

FN4_M5

FN4_M6

FN4_M13

FN9_M1

FN9_M2

FN9_M4

FN9_M6

FN9_M12

FN10_M1

FN10_M2

FN10_M3

FN10_M4

FN10_M5

FN10_M6

FN10_M12

FN11_M11

FN11_M12

FN11_M13

FN11_M14

FN12_M11

FN12_M13

FN12_M14

FN12_M15

Bank 1Bank 2

U10C

XC2C128

Bank 1Bank 2

U10C

XC2C128

R16

66.5

R16

66.5

C11

10NF

C11

10NF

C20

10NF

C20

10NF

Gnd

Out

Vreg

TPS76201

Vreg

TPS76201

C14

1UF

C14

1UF

C13

10NF

C13

10NF

C23

1UF

C23

1UF

R18

0 ohm

NOPOP

R18

0 ohm

NOPOP

R2110k R2110k

J32

SMT

J32

SMT

C21

100N

C21

100N

1UF

33UF

R19

0 ohm

R19

0 ohm

GND1

GND2

GND3

GND4

GND5

GND7

GND8

100

GND6

VCC1

VCC2

VCCIO1-1

VCCIO1-2

VCCIO1-3

VCCIO2-1

VCCIO2-2

U10A

XC2C128

U10A

XC2C128

C15

10NF

C15

10NF

TCK

TDI

TDO

TMS

VCCAUX

U10B

XC2C128

U10B

XC2C128

C12

100N

C12

100N

C10

100N

C10

100N

R2310k R2310k

R20

0 ohm

NOPOP

R20

0 ohm

NOPOP

C18

10NF

C18

10NF

R1010 R1010

R15

0 ohm

R15

0 ohm

R14

R45

113

R45

113

C16

10NF

C16

10NF

Figure 6. CPLD

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

Rev. 0.6 15

EVB_SER_NUM

VBUS

V3P3

SS_CPLD_B

MISO

SCLK

CPLD_IRQ

MOSI

MCU_SPARE1

MCU_SPARE2

REG_ADR0

REG_ADR1

REG_ADR2

REG_ADR3

REG_ADR4

MCU_LED1

MCU_LED2

CPLD_RST_B

MCU_LED3

CPLD_SPARE1

CPLD_SPARE2

CPLD_SPARE4

CPLD_SPARE5

CPLD_SPARE6

CPLD_SPARE7

CPLD_SPARE8

CPLD_SPARE9

CPLD_SPARE10

CPLD_SPARE11

CPLD_SPARE12

CPLD_SPARE13

CPLD_SPARE14

CPLD_SPARE15

CPLD_SPARE16

USB

serial number

Install 1.5K pullups

for I2C operation.

On MCU:

P0.0 = SDA

P0.1 = SCL

MCU debug

reset

Spares

R12

10k

R12

10k

1UF

Vdd

GND

RST/C2CK

C2D

REGIN

VBUS

D+

D-

P0.0

P0.1

P0.2

P0.3

P0.4

P0.5

P0.6

P0.7

P1.0

P1.1

P1.2

P1.3

P1.4

P1.5

P1.6

P1.7

P3.7

P3.6

P3.5

P3.4

P3.3

P3.2

P3.1

P3.0

P2.0

P2.1

P2.2

P2.3

P2.4

P2.5

P2.6

P2.7

P4.7

P4.6

P4.5

P4.4

P4.3

P4.2

P4.1

P4.0

C8051-

F340

Si8051F340

C8051-

F340

Si8051F340

R38

0 ohm

R38

0 ohm

100N

R40

R44

10k

SW1

R127.4 R127.4

R1749.9 R1749.9

C37

100N

C37

100N

10k

R310k R310k

NC1

NC2

Gnd1

Gnd2

USB Clamp

SN65220

USB Clamp

SN65220

R46

10k

R46

10k

R13

1.5K

NOPOP

R13

1.5K

NOPOP

R4149.9 R4149.9

R39

910

J31

10_M_Header_SMT

J31

10_M_Header_SMT

R749.9 R749.9

Gnd

D-

D+

USB

100N

Vcc

GND

I/O

NC1

NC2

NC3

Ser No.

DS2411

Ser No.

DS2411

R1149.9 R1149.9

1UF

Vcc

Vss

Clk

HOLD

EEPROM

M95040

EEPROM

M95040

R42

49.9

R42

49.9

R37

910

J34

10_M_Header_SMT

BOM = NOPOP

J34

10_M_Header_SMT

BOM = NOPOP

R43

NOPOP

R43

NOPOP

C36

100N

C36

100N

27.4

NC1

NC2

Gnd1

Gnd2

USB Clamp

SN65220

USB Clamp

SN65220

C38

100N

C38

100N

Figure 7. MCU

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

16 Rev. 0.6

V3P3_LED

V3P3

DUT_PWR

CPLD_LED0

MCU_LED1

MCU_LED2

MCU_LED3

CPLD_LED1

CPLD_LED2

CPLD_LED3

CPLD_LED4

CPLD_LED5

CPLD_LED6

CPLD_LED7

CPLD_LED8

CPLD_LED9

FS_SW

FS_ALIGN

DSBL34

CK_CONF

CS0_C3A

DEC

INC

CS1_C4A

C1A

C2A

INT_ALRM

C1B

C2B

C3B

LOL

CPLD_LED10

EVB

main

power

3.3V

3.3Vreturn

DUT_PWR

DUT_PWRreturn

+3.3V

ground

pins

mounting holes

two

level

inputs

status

C4A

C3A

C2A

C1A

C3B

C2B

C1B

LOL

+3.3V

DUT_PWR

INT_ALRM

CPLD_1

MCU_1

MCU_2

MCU_3

CPLD_2

D7 Yel

R730 ohm R730 ohm

R65

10k

R65

10k

D5 Red

R27 100R27 100

R33R150x4 R33R150x4

J11J11

D12 Grn

J19J19

D4 Red

1 2

Ferrite

J20J20

R71

R48

0 ohm

R48

0 ohm

R69

J40

Phoenix_4_screw

J40

Phoenix_4_screw

2 3

BSS138

J27

BOM = NOPOP

J27

BOM = NOPOP

C35

330UF

C35

330UF

R35R150x4 R35R150x4

R34R150x4 R34R150x4

D14 Grn

J24J24

R66

10k

R66

10k

C31

33UF

C31

33UF

D6 Red

D13 Red

1 8

2 7

3 6

4 5

R47R82x4 R47R82x4

C30

33UF

C30

33UF

J12J12

R49

82.5

R49

82.5

J26J26

D11 Red

1 8

2 7

3 6

4 5

R6R82x4 R6R82x4

D16 Grn

D3 Grn

R6310k R6310k

D8 Red

910

1112

1314

1516

1718

1920

20_M_Header_SMT

IN7

IN6

IN5

IN4

IN3

IN2

IN1

IN0

Vcc

GND

OE1

OE2

Buffer

74LCX541

Buffer

74LCX541

J4J4

D1 Grn

C34

330UF

C34

330UF

10A

10B

5C5A

3A 3C

10C

J14

10x3_M_HDR_SMT

J14

10x3_M_HDR_SMT

D9 Yel

R68 10kR68 10k

D10 Grn

IN7

IN6

IN5

IN4

IN3

IN2

IN1

IN0

Vcc

GND

OE1

OE2

Buffer

74LCX541

Buffer

74LCX541

J9J9

J16J16

D15 Red

D2 Red

R32R150x4 R32R150x4

Figure 8. Power, LEDs and 2L Inputs

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

Rev. 0.6 17

DUT_PWR

FRQTBL

AUTOSEL

SFOUT1

RATE1

FOS_CTL

RATE0

DBL_FS

DBL2_BY

SDA_SDO_BWSEL1

A0_FRQSEL0

SFOUT0

SCL_SCLK_BWSEL0

SDI_FRQSEL3

DIV34_1

A2_SS_FRQSEL2

DIV34_0

CMODE

A1_FRQSEL1

DUT_RST_B

three

level

inputs

SPI, I2C

port

install

for I2C

see note 2

10A

10B

5C5A

3A 3C

15A

13B

16A

16B

17B

17A

16C

13C

11C

12A

11A

14B

15B

17C

10C

11B

14A

15C

13A

12B

12C

14C

19B

18C

20B

19A 19C

18B

20C20A

18A

J17

20x3_M_HDR_SMT

J17

20x3_M_HDR_SMT

R22

1.5K

NOPOP

R22

1.5K

NOPOP

R2610 R2610

910

J22

10_M_Header_SMT

J22

10_M_Header_SMT

R7210k R7210k

R620 ohm

NOPOP

R620 ohm

NOPOP

R7010k R7010k

R640 ohm

NOPOP

R640 ohm

NOPOP

R67

R82x4

R67

R82x4

R58

100

R58

100

R25

1.5K

NOPOP

R25

1.5K

NOPOP

Notes:

2. NOPOP for Si5365 and Si55366.

Figure 9. Serial Port, 3L Inputs

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

18 Rev. 0.6

9. Bill of Materials

Table 9. Si536x Bill of Materials

Item Qty Reference Part Mfgr MfgrPartNum

1 32 C1,C2,C3,C5,C10,C12,C17,C19,C21

,C25,C26,C27,C28,C29,C32,C33,C3

6,C37,C38,C40,C42,C44,C45,C47,C

49,C50,C53,C55,C57,C58,C60,C61

100 N Venkel C0603X7R160-104KNE

2 7 C4,C6,C8,C9,C14,C23,C52 1 UF Venkel C0603X7R6R3-

105KNE

3 3 C7,C30,C31 33 UF Venkel TA0006TCM336MBR

4 16 C11,C13,C15,C16,C18,C20,C24,C41

,C43,C46,C48,C51,C54,C56,C59,C6

10 NF Venkel C0603X7R160-103KNE

6 2 C34,C35 330 UF Panasonic EEE-HA0J331XP

7 6 D1,D3,D10,D12,D14,D16 Grn Lumex SML-LXT0805GW-TR

8 8 D2,D4,D5,D6,D8,D11,D13,D15 Red Lumex SML-LXT0805SRW-TR

9 2 D7,D9 Yel Lumex SML-LXT0805YW-TR

10 4 H1,H2,H3,H4 #4 mounting hole

11 20 J1,J2,J3,J5,J7,J10,J13,J15,J21,J23,

J28,J29,J30,J33,J35,J36,J37,J38,J3

9,J41

SMA_EDGE Johnson 142-0701-801

12 9 J4,J9,J11,J12,J16,J19,J20,J24,J26 Jmpr_1pin

13 1 J6 USB FCI 61729-0010BLF

14 1 J8 20_M_Header_SMT Samtec HTST-110-01-lm-dv-a

15 1 J14 10x3_M_HDR_SMT Samtec TSM-110-01-L-TV

16 1 J17 20x3_M_HDR_SMT Samtec TSM-120-01-L-TV

17 1 J18 Jmpr_2pin

18 1 J22 10_M_Header_SMT Samtec HTST-105-01-lm-dv-a

20 1 J31 10_M_Header_SMT Samtec HTST-105-01-lm-dv-a

21 1 J32 SMT Sullins GZC36SABN-M30

23 1 J40 Phoenix_4_screw Phoenix MKDSN 1.5/4-5.08

24 2 L1,L2 Ferrite Venkel FBC1206-471H

25 1 Q1 BSS138 On Semi BSS138LT1G

26 2 R1,R2 27.4 Venkel CR0603-16W-27R4FT

27 13 R3,R4,R9,R12,R21,R23,R46,R63,

R65,R66,R68,R70,R72

10 k Venkel CR603-16W-1002FT

28 6 R5,R37,R40,R44,R69,R71 1 K Venkel CR0603-16W-1001FT

29 3 R6,R47,R67 R82x4 Panasonic EXB-38V820JV

30 15 R7,R11,R17,R24,R41,R42,R52,R53,

R54,R55,R56,R57,R59,R60,R61

49.9 Venkel CR0603-16W-49R9FT

Table 9. Si536x Bill of Materials (Continued)

Item Qty Reference Part Mfgr MfgrPartNum

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

Rev. 0.6 19

33 9 R15,R19,R28,R29,R31,R36,R38,

R48,R73

0 ohm Venkel CR0603-16W-000T

34 1 R16 66.5 Venkel CR0603-16W-66R5FT

36 2 R27,R58 100 Venkel CR0603-16W-1000FT

37 4 R32,R33,R34,R35 R150x4 Panasonic EXB-38V151JV

39 1 R45 113 Venkel CR0603-16W-1130FT

40 1 R49 82.5 Venkel CR0603-16W-82R5FT

42 1 SW1 NO Mountain Switch 101-0161-EV

43 2 U1,U2 SN65220 TI SN65220DBVT

44 1 U3 DS2411 Maxim/Dallas DS2411P

45 1 U4 TPS76201 TI TPS76201DBVT

46 1 U5 M95040 ST Micro M95040-WMN6P

47 1 U6 Si5368A-X-GQ* Silicon Labs Si5368A-X-GQ

48 2 U7,U8 74LCX541 Fairchild 74LCX541MTC_NL

49 1 U9 Si8051F340 Silicon Labs C8051F340-GQ

50 1 U10 XC2C128 Xilinx XC2C128-7VQG100I

51 1 X1 for Si5365/66-EVB and

Si5367/68-EVB

114.285 MHz TXC 7MA1400014

51 1 X1 for the Si5369-EVB 114.285 MHz, 20 ppm NDK EX500A-C500997

Not Populated

5 2 C22,C39 10 NF Venkel C0603X7R160-103KNE

19 2 J25,J27 Jmpr_2pin

22 1 J34 10_M_Header_SMT Samtec HTST-105-01-lm-dv-a

32 3 R13,R22,R25 1.5 K Venkel CR0603-16W-1501FT

35 6 R18,R20,R30,R50,R62,R64 0 ohm Venkel CR0603-16W-000T

38 1 R43 1 K Venkel CR0603-16W-1001FT

41 1 R51 100 Venkel CR0603-16W-1000FT

*Note: X denotes the product revision. Consult the ordering guide in the Si5368 Data Sheet for the latest product revision.

For the Si5365/66-EVB, substitute Si5366-C-GQ. For the Si5369-EVB, substitute Si5369A-C-GQ.

Table 9. Si536x Bill of Materials (Continued)

Item Qty Reference Part Mfgr MfgrPartNum

Si5365/66-EVB Si5367/68-EVB Si5369-EVB

20 Rev. 0.6

10. Layout

Figure 10. Silkscreen Top

Figure 11. Layer 1

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